A new optimal foraging model predicts habitat use by drift‐feeding stream minnows

Grossman, Gary D.; Rincón, Pedro A.; Farr, Mark D.; Ratajczak, Robert E.

doi:10.1034/j.1600-0633.2002.110102.x

Cited by 70 publications

(129 citation statements)

References 32 publications

(66 reference statements)

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“…Rosenfeld and Taylor, 2009). With additional assumptions, they have been used to predict larger spatial patterns of biomass distribution or capacity (Grossman et al, 2002;Hayes et al, 2007;Hughes, 1998), but a remaining challenge is linking spatial patterns of growth and survival to population viability (Anderson et al, 2006b;Armstrong and Nislow, 2012;Frank et al, 2011;Locke et al, 2008). Individual-based modeling (IBM) approaches based on the bioenergetics of specific life stages for individual fish have been the most successful at this integration and have shown great utility in river management contexts (Van Winkle et al, 1998;Vincenzi et al, 2008).…”

Section: Discussionmentioning

confidence: 99%

Modeling the influence of flow on invertebrate drift across spatial scales using a 2D hydraulic model and a 1D population model

Anderson

Harrison

Nisbet

et al. 2013

Ecological Modelling

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a b s t r a c tMethods for creating explicit links in environmental flow assessments between changes in physical habitat and the availability and delivery rate of macroinvertebrates that comprise fish diets are generally lacking. Here, we present a hybrid modelling approach to simulate the spatial dynamics of macroinvertebrates in a section of the Merced River in central California, re-engineered to improve the viability of Chinook salmon. Our efforts focused on quantifying the influence of the hydrodynamic environment on invertebrate drift dispersal, which is a key input to salmon bioenergetics models. We developed a twodimensional hydrodynamic model that represented flow dynamics well at baseflow and 75% bankfull discharges. Hydraulic predictions from the 2D model were coupled with a particle tracking algorithm to compute drift dispersal, where the settling rates of simulated macroinvertebrates were parameterized from the literature. Using the cross-sectional averaged velocities from the 2D model, we then developed a simpler 1D representation of how dispersal distributions respond to flow variability. These distributions were included in 1D invertebrate population models that represent variability in drift densities over reach scales. Dispersal distributions in the 2D simulation and 1D representation responded strongly to spatial changes in flow. When included in the 1D population model, dispersal responses to flow 'scaled-up' to yield distributions of drifting macroinvertebrates that showed a strong inverse relationship with flow velocity. The strength of the inverse relationship was influenced by model parameters, including the rate at which dispersers settle to the benthos. Finally, we explore how the scale of riffle/pool variability relative to characteristic length scales calculated from the 1D population model can be used to understand drift responses for different settling rates and at different discharges. We show that, under the range of parameter values explored, changes in velocity associated with transitions between riffles and pools produce local changes in drift density of proportional magnitude. This simple result suggests a means for confronting model predictions against field data.

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Section: Discussionmentioning

confidence: 99%

Modeling the influence of flow on invertebrate drift across spatial scales using a 2D hydraulic model and a 1D population model

Anderson

Harrison

Nisbet

et al. 2013

Ecological Modelling

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“…Fish are thought to occupy microhabitats that maximize their net energy intake (Milinski, 1993). This approach has been used to predict microhabitat of several fish species (Fausch, 1984;Hughes and Dill, 1990;Grossman et al, 2002). Not a single approach to modelling will fit all needs; however, hydraulically based models are popular and relatively simple to apply across numerous streams compared to energetically based models.…”

Section: Discussionmentioning

confidence: 99%

Influence of cover on mean column hydraulic characteristics in small pool riffle morphology streams

Smith

Brannon

2007

River Research & Apps

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The field of ecohydraulics tries to link biological-and physical-based processes in order to describe better the distribution of plants and animals in rivers. We tested the hypothesis that the influence of cover in pools and riffles would not be detectable using average velocity, turbulent kinetic energy and turbulent intensity, and compared these measurements to locations distant from cover. We measured water velocity fluctuations using an acoustic Doppler velocimeter. We found that turbulent intensity in the downstream direction (u 0 ) and the transverse or cross-stream direction (v 0 ) were the most useful in detecting the presence of cover in pools and riffles. Differences were apparent between locations near cover in pools and riffles. Turbulent kinetic energy (k) and vertical turbulent intensity (w 0 ) detected cover in pools but not in riffles. Average downstream velocity (u) detected cover in riffles but not in pools. Average cross-stream (v) and vertical (w) velocities did not detect any differences at all. We rejected the null hypothesis and concluded that turbulence caused by habitat features such as large rocks, wood or other channel complexities results in a statistically meaningful difference in flow characteristics in locations near cover. This finding was tempered by the fact that knowledge about how fish respond to turbulence is limited in comparison to our understanding of average velocity values. Despite the potential benefits to habitat modelling of incorporating turbulence-based metrics, application of these findings will be challenging because turbulence modelling is difficult and current models may not be appropriate for application to rivers.

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“…Drift-feeding Wshes also are important components of stream Wsh faunas worldwide (Matthews 1998); thus, studies of their dynamics have the potential for generality. To brieXy describe this system, drift-feeding Wshes typically hold relatively stable foraging positions in running water from which they dash to strike at macroinvertebrates carried downstream by the current (i.e., drift) (Hughes and Dill 1990;Hill and Grossman 1993;Grossman et al 2002). Swimming to hold position against a current may impose substantial energetic costs on driftfeeding Wshes (Facey and Grossman 1990), and, at velocities higher than about 5-10 cm/s, current speed can negatively aVect the ability of Wshes to capture drifting prey (Hill and Grossman 1993;Tyler 1993;Grossman et al 2002).…”

Section: Introductionmentioning

confidence: 99%

“…To brieXy describe this system, drift-feeding Wshes typically hold relatively stable foraging positions in running water from which they dash to strike at macroinvertebrates carried downstream by the current (i.e., drift) (Hughes and Dill 1990;Hill and Grossman 1993;Grossman et al 2002). Swimming to hold position against a current may impose substantial energetic costs on driftfeeding Wshes (Facey and Grossman 1990), and, at velocities higher than about 5-10 cm/s, current speed can negatively aVect the ability of Wshes to capture drifting prey (Hill and Grossman 1993;Tyler 1993;Grossman et al 2002). However, Wshes still occupy foraging positions with velocities higher than 10 cm/s because encounter rates with drifting prey generally increase with increasing current velocity (Hughes and Dill 1990;Grossman et al 2002).…”

Section: Introductionmentioning

confidence: 99%

Form and performance: body shape and prey-capture success in four drift-feeding minnows

2007

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Identifying links between morphology and performance for ecologically relevant tasks will help elucidate the relationships between organismal design and fitness. We conducted a laboratory study to quantify the relationship between variation in body shape and prey-capture success in four drift-feeding minnow species. We offered drifting prey to individual fish in a test flume, counted successful strikes to measure prey-capture success and recorded the position (X, Y coordinates) of ten landmarks on each fish's outline to delineate the specimen's form. We then quantified shape variation among species and related it to capture performance through thin-plate spline analysis. Body shape varied significantly among species and with specimen size and was the major determinant of capture success, explaining 45-47% of its variability. Prey-capture success at differing velocities differed among species, but once the effects of shape and size were accounted for, those differences were no longer significant. Allometric shape changes appeared responsible for most of the ontogenetic variation in capture performance, although other size-related, non-shape factors also seemed relevant. Fishes with deeper, shorter bodies, more caudally placed median fins and larger, more upward-pointing mouths exhibited greater capture success than more fusiform fish, suggesting that streamlining, which is energetically advantageous for sustained swimming, entails a cost in terms of prey-capture ability. Our findings demonstrate a strong connection between organismal shape and performance and provide empirical evidence of the cost of morphological specialization for fishes in the drift-feeding functional guild.

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A new optimal foraging model predicts habitat use by drift‐feeding stream minnows

Cited by 70 publications

References 32 publications

Modeling the influence of flow on invertebrate drift across spatial scales using a 2D hydraulic model and a 1D population model

Modeling the influence of flow on invertebrate drift across spatial scales using a 2D hydraulic model and a 1D population model

Influence of cover on mean column hydraulic characteristics in small pool riffle morphology streams

Form and performance: body shape and prey-capture success in four drift-feeding minnows

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